JP3552737B2 - Surgical microscope - Google Patents

Description

[0001]
[Industrial applications]
The present invention relates to a surgical microscope including an objective optical system capable of moving an object-side focal position, and an illumination optical system that irradiates a target portion.
[0002]
[Prior art]
In recent years, with the development of surgical techniques and surgical tools, fine surgery, so-called microsurgery, has been frequently performed. For this microsurgery, an operating microscope for enlarging and observing an operation site is used.
[0003]
Generally, a surgical microscope is a stereoscopic microscope as shown in FIG. 8, a mirror body 101, an arm 102 for moving and fixing the mirror body 101 to a desired position and angle, and supports the arm. And a pedestal section 103 for mounting.
[0004]
Usually, the mirror unit 101 is held by the arm 102 so as to be moved along the observation optical axis direction by a focusing unit (not shown) so as to perform a focusing operation. Instead of the focusing unit, a so-called variable focal length objective optical system that changes a focal position by moving a specific lens in the optical axis direction has been used.
[0005]
Hereinafter, the mirror unit 101 having the variable focal length objective optical system will be described with reference to FIG. In the figure, 104 is a variable focal length objective optical system, 105 is a variable magnification optical system, 106 is an aperture stop, 107 is an image forming lens, and 108 is an eyepiece. The variable power optical system 105, the aperture stop 106, the imaging lens 107, and the eyepiece 108 are arranged in pairs on the left and right in the direction perpendicular to the plane of the drawing. Reference numeral 109 denotes an illumination prism disposed behind (upper side in the figure) the objective lens 104; 110, an illumination optical system; 111, an illumination field stop disposed in a plane optically conjugate with the surgical site P; A condenser lens 113 is a lamp as a light source. Also, O₁  Is the observation optical axis in the mirror unit 101, O₂  Is the illumination optical axis.
[0006]
In this configuration, the illumination light emitted from the lamp 113 is condensed via the condenser lens 112 and narrowed down by the illumination field stop 111, and then the illumination optical system 110, the illumination prism 109, and the variable focal length objective optical system. The operative site P is irradiated via the system 104. On the other hand, the light emitted from the operative site P is imaged by the imaging lens 107 via the variable focal length objective optical system 104, the variable power optical system 105, and the aperture stop 106, and is then enlarged by the eyepiece 108. Then, a stereoscopic observation is performed by the operator's eye E.
[0007]
During the operation, the surgeon operates the variable focal length objective optical system 104 by input means such as a foot switch (not shown) in order to focus on the operative site P, and specifies the focal length included in the variable focal length objective optical system 104. The lens group is moved to focus. At this time, usually, the observation total magnification, that is, the observation visual field diameter changes due to the change of the focal length. However, even if the focal length changes, the observation total magnification, that is, the observation visual field diameter does not change. Japanese Patent Application Laid-Open No. 63-60418 discloses a variable focal length objective optical system that corrects the total observation magnification by the variable magnification optical system 105 in response.
[0008]
Further, when the operative portion P is a deep and long hole such as a pore, or when utilizing the red reflection of the fundus in lens extraction in ophthalmic surgery, the illumination prism 109 in FIG. And the observation optical axis O₁  And illumination optical axis O₂  That is, a so-called perfect coaxial illumination in which a half mirror is arranged so as to coincide with the above is used. This perfect coaxial illumination is disclosed in Japanese Patent Application Laid-Open No. 63-27810. Hereinafter, a case in which the above-described variable focal length objective optical system is applied to a perfect coaxial illumination disclosed in Japanese Patent Application Laid-Open No. 63-27810 will be described with reference to FIG.
[0009]
In the figure, reference numeral 114 denotes an illumination optical axis O₂  A pupil filter which is disposed at a position optically conjugate with the operation part P, that is, the same position as the illumination field stop 111, an illumination light path switching mirror 115 which can move between a position indicated by a solid line and a position indicated by a broken line in the drawing, 116 is the observation optical axis O₁  And illumination optical axis O₂  A half mirror 117 is disposed so that its reflection surface is located at the intersection with the half mirror 116, and a dustproof cover attached to the operation portion P side of the half mirror 116. The pupil filter 114, the illumination light path switching mirror 115, the half mirror 116, the dust cover 117, the illumination optical system 110, the illumination field stop 111, the condenser lens 112, and the lamp 113 are all housed integrally in a frame body 118. Constitutes a lighting unit, via a frame 118Mirror 101It is integrally attached to. In the drawings, the same members as those in FIG. 9 are denoted by the same reference numerals as in FIG.
[0010]
In this configuration, the illumination light emitted from the lamp 113 is condensed by the condenser lens 112, then passes through the illumination optical system 110, and is guided to the surgical site P without passing through the variable focal length objective optical system 104. I will When the illumination light path switching mirror 115 is arranged at the position indicated by the solid line in the drawing, the illumination light transmitted through the illumination optical system 110 is reflected by the illumination light path switching mirror 115 and becomes the observation optical axis O.₁  At a certain angle with respect to the operation part P. When the illumination light path switching mirror 115 is disposed at a position indicated by a broken line in the figure, the illumination light is reflected by the half mirror 116 and then reflected by the observation optical axis O.₁  Is irradiated to the operative site P along.
[0011]
Further, since the pupil filter 114 is disposed in a plane optically conjugate with the operation part P, an image thereof is formed on the operation part P, that is, on the pupil of the patient. Therefore, the operation can be performed without protecting the patient's retina, that is, without damaging the patient's eye. Further, since the illumination field stop 111 is disposed at the position of the pupil filter 114, a clear outline of the visual field is formed on the operative site P.
[0012]
[Problems to be solved by the invention]
By the way, in the configuration as shown in FIG. 9 in which the illumination light is guided to the operative site P via the variable focal length objective optical system 104, the lenses of the lens group that constitute the variable focal length objective optical system 104 There is a problem in that the light is reflected on the surface, and the reflected light enters the variable power optical system 105, and flare occurs in the observation visual field. Since the reflected light is generated on each lens surface constituting the variable focal length objective optical system 104, the reflected light is transmitted to the variable focal length objective optical system 104 having a larger number of constituent lenses than an objective lens having a fixed focal length. In that case, the influence on the observation optical system becomes large.
[0013]
In the case of an objective lens having a fixed focal length, the direction of reflection of the reflected light can be made constant, so that the illumination prism 109 is configured so that the reflected light does not enter the observation field, that is, flare does not occur. Although it is possible to dispose them, in the variable focal length objective optical system 104, the lens group constituting the objective optical system 104 has an observation optical axis O₁  Since it moves along the direction, it is very difficult to configure and arrange the illumination prism 109 so that flare does not occur.
[0014]
In the configuration shown in FIG. 9, the illumination prism 109 is replaced with a half mirror, that is, the observation optical axis O is provided between the variable focal length objective optical system 104 and the variable power optical system 105.₁  And illumination optical axis O₂  When the so-called perfect coaxial illumination in which the reflecting surface of the half mirror is arranged so that₁  Since reflected light is generated above, the flare generation rate is further increased.
[0015]
In order to avoid such a flare problem, as shown in FIG. 10, the observation optical system in the mirror unit 101 and the illumination unit 118 having the illumination optical system 110 are formed separately, and the illumination light has a variable focal length. In a case where the irradiation is performed on the operation site P without passing through the objective optical system 104, if the focal position is changed by operating the variable focal length objective optical system 104, the illuminated field is changed with the change of the focal position. The conjugate positional relationship between the diaphragm 111 and the operative site P cannot be maintained, the contour of the illuminated field is blurred, and flare is generated by scattered light generated around the operative site P, and the illumination efficiency is also poor. turn into.
[0016]
Furthermore, when the focal length is changed by the variable focal length objective optical system 104 and the total observation magnification is corrected by the variable power optical system 105, the illumination magnification of the illumination optical system is always constant despite the observation field diameter does not change. Since it is constant, depending on the focal length, a defect such as irradiating the illumination light to the outside of the observation visual field or irradiating only a part of the observation visual field occurs at the surgical site P, and the illumination efficiency becomes extremely poor. Would.
[0017]
Furthermore, in ophthalmic surgery, for the purpose of protecting the patient's retina,FIG.The pupil filter 114 is arranged at the position of the illumination field stop 111 as shown in (1), and the image of the pupil filter 114 is projected on the pupil. The conjugate positional relationship between the filter 114 and the operative part P, that is, on the patient's pupil is broken, and the image of the pupil filter 114 is blurred on the operative part P. Danger to the eye of one patient. In this state, if the aperture stop 106 is stopped down to increase the depth of focus, it goes without saying that the illumination efficiency is further deteriorated.
[0018]
As described above, it is also important to eliminate the problem of flare, but this time, the present inventor has paid particular attention to improving the lighting efficiency, in addition to the problem of flare. An object of the present invention is to provide a surgical microscope which can always obtain the best illumination condition at any focal length and has high safety.
[0019]
[Means for Solving the Problems]
In order to solve the above problem, an operation microscope according to the first aspect of the present invention includes an observation optical system for an operator to observe a subject, and a focus position changing unit capable of changing a focus position of the observation optical system. A light source capable of emitting illumination light for illuminating an observation position of the subject observed by the observation optical system, and a light source that is arranged on an optical path of the illumination light from the light source to the observation position; Illumination magnification changing means for changing the illumination magnification of the illumination light applied to the observation position in accordance with the change of the focal position by the change means; and illumination of the illumination light for restricting the luminous flux of the illumination light and illuminating the observation position An illumination area changing unit for changing an area, and changing the illumination magnification of the illumination magnification changing unit so that the illumination area changing unit is disposed at a position conjugate to the observation position on an optical path of the illumination light. According to the lighting times And having a positional relationship changing means for changing the relative positional relationship between the changing means and said illumination region changing means.
The surgical microscope according to claim 2, wherein an observation optical system for an operator to observe the subject, a focus position changing unit capable of changing a focus position of the observation optical system, and the observation optical system for the subject. A light source capable of emitting illumination light for illuminating an observation position to be observed by the system; and a light source that is disposed on an optical path of the illumination light from the light source to the observation position. Illumination magnification changing means for changing the illumination magnification of the illumination light irradiating the observation position in accordance with the illumination light; and an illumination magnification change unit disposed at a predetermined position on the optical path of the illumination light to restrict the light flux of the illumination light to the observation position. TeruShootingIllumination of the illumination lightregionAn illumination area changing unit that changes the illumination magnification, and a position conjugate with the observation position on the optical path of the illumination light according to a change in the illumination magnification of the illumination magnification changing unit. Conjugate position changing means for changing to a position.
[0020]
[Action]
In the first aspect of the present invention,By means of focus position changeWhen the focus position of the observation optical system moves,The illumination magnification changing unit changes the illumination magnification of the illumination light applied to the observation position in accordance with the change of the focal position, and the illumination area changing unitBy the action ofThe luminous flux of the illumination light is restricted, and the illumination area of the illumination light illuminated at the observation position is changed. At this time, the illumination magnification is changed by the illumination magnification changing means so that the illumination area changing means is arranged at a position conjugate to the observation position on the optical path of the illumination light by the positional relationship changing means. The relative positional relationship between the changing means and the illumination area changing means is changed.
According to the second aspect of the present invention, when the focal position of the observation optical system is moved by the focal position changing means, the illumination magnification of the illumination light applied to the observation position is changed by the illumination magnification changing means according to the change of the focal position. In addition, by the operation of the illumination area changing means, the luminous flux of the illumination light is restricted, and the illumination area of the illumination light illuminated at the observation position is changed. At this time, a position conjugate with the observation position on the optical path of the illumination light is changed to the predetermined position by the conjugate position changing means according to the change of the illumination magnification by the illumination magnification changing means.
[0021]
【Example】
Hereinafter, embodiments of the present invention will be described with reference to the drawings. 1 and 2 show a first embodiment of the present invention. The mirror 1 of the surgical microscope according to the present embodiment is attached to a gantry (not shown), and is specifically configured as shown in FIG. That is, reference numeral 2 in the drawing denotes a variable focal length objective optical system that changes the focal length by changing the distance between lens groups formed by operating input means (for example, a foot switch) not shown. Reference numeral 3 denotes a lens frame (not shown) that holds a lens group that constitutes the variable focal length objective optical system 2 by rotating the observation optical axis O.₁  A lens group moving member that moves in a direction to change a relative position of the lens group. Reference numeral 4 denotes a gear integrally attached to the lens group moving member 3.
[0022]
Reference numeral 5 denotes a gear arranged so as to mesh with the gear 4, and the rotation axis of a motor 6 fixed inside the mirror body 1 is attached to the center axis of the gear. Reference numeral 7 denotes a variable power lens arranged in a pair on the left and right in the direction perpendicular to the paper surface, which is configured to correct a change in the total observation magnification when the focal length of the variable focal length objective optical system 2 changes. I have. Reference numeral 8 denotes an imaging lens arranged in a pair on the left and right in the direction perpendicular to the paper, and reference numeral 9 similarly denotes an eyepiece arranged in a pair on the left and right in the direction perpendicular to the paper.
[0023]
Reference numeral 10 denotes a lamp for irradiating illumination light, and 11 denotes a condenser lens. Reference numeral 12 denotes an illumination optical axis O₂  The center axis and the illumination optical axis O are optically conjugate with the upper surgical site P.₂  Is the illuminated aperture arranged so as to coincide with. Reference numeral 13 denotes an illumination field stop frame that holds the illumination field aperture 12, 14 denotes a rack integrally attached to the illumination field aperture frame 13, and 15 denotes a gear that is arranged to mesh with the rack 14.
[0024]
Reference numeral 16 denotes an illumination optical system that changes an illumination magnification by changing an interval between constituent lens groups. Reference numeral 17 denotes a lens frame (not shown) holding a lens group constituting the illumination optical system 16 with the rotation of the illumination optical axis₂  A lens group moving member that moves in the direction and changes the relative position of the lens group. Reference numeral 18 denotes a gear integrally attached to the lens group moving member 17, and 19 denotes a gear arranged to mesh with the gear 18.
[0025]
Reference numeral 20 denotes an observation optical axis O in front of the variable focal length objective optical system 2 inside the mirror unit 1 (lower side in the figure) so as to guide the illumination light via the illumination optical system 16 to the operation site P.₁  And illumination optical axis O₂  Is an illumination prism arranged and fixed so as to form a certain angle. Reference numeral 21 indicates that the input shaft is configured as the output shaft of the motor 6, the center of the gear 5 is integrally attached to the input shaft, and the two output shafts are the gear 15 and the gear 19. The center is a gear box integrally attached to each.
[0026]
In the mirror body 1 having the above-described configuration, when input means (not shown) is operated to focus on the operative site P, the motor 6 is driven according to the operation signal, and the motor 6 is driven via the gear 5 and the gear 4. The lens group moving member 3 is rotated. When the lens group moving member 3 rotates, a specific lens group among the lens groups constituting the variable focal length objective optical system 2 is moved to the observation optical axis O.₁  , The relative position of the lens group changes, and the focal length changes while the observation magnification is kept constant by the action of the variable power optical system 7 to focus on the surgical site P. That is, the surgeon can perform focusing in a state where the observation visual field diameter is constant, regardless of the distance between the mirror section 1 and the surgery section P.
[0027]
Further, since the output shaft of the motor 6 is formed integrally with the input shaft of the gear box 21, the gear 19 rotates with the rotation of the lens group moving member 3. Accordingly, the lens group moving member 17 is rotated via the gear 18 that meshes with the gear 19, and a specific lens group among the illumination lenses that constitute the illumination optical system 16 has an illumination optical axis O.₂  Move along. As a result, the relative positions of the lens groups constituting the illumination optical system 16 change, and the illumination magnification is set so that the observation field diameter always matches the illumination field diameter.
[0028]
Further, the gear 15 is rotated by the other output shaft of the gear box 21, and the illumination field stop frame 13 is moved via the rack 14 in an oblique direction indicated by an arrow in the drawing. That is, the illumination field stop 12 is always arranged at a position conjugate with the operation site P. Specifically, as shown in FIG. 2, with respect to the operative site P, the illumination field stop 12 is always arranged at a position conjugate with the operative site P, that is, at the position of O in the drawing. Observation optical axis O₁And illumination optical axis O₂Is matched on the operative site P, so that the image of the illumination field stop 12 is formed on the operative site P by the illumination optical system 16 with the center of the observation visual field and the center of the illuminated field coincide. Further, with respect to the operative part P ', the illumination field stop 12 is arranged at the position of O' in the figure by moving along the oblique direction shown by the arrow in the figure. At this time, the illumination optical axis is O₂′, And the observation optical axis O₁And illumination optical axis O₂'Matches. Further, with respect to the surgical site P ", the illumination optical axis becomes O by moving the illumination field stop 12 to the position O".₂And similarly, the observation optical axis O on the surgical site P "₁And illumination optical axis O₂As described above, the image of the illumination field stop 12 always has a state in which the illumination field diameter matches the observation field diameter and the center of the illumination field coincides with the center of the observation field on the surgical site. Thus, an image is formed on the operation site.
In other words, the operating microscope according to the present embodiment can change the focus positions of the observation optical systems 2, 7, 8, 9 for observing the subject and the observation optical systems 2, 7, 8, 9 A light source 10 capable of emitting illumination light for illuminating the observation position of the subject by the observation optical systems 2, 7, 8, 9; The focus position changing means 2, 3, 4, 5, and 6 change the focus so that the emitted illumination light is applied to the first illumination area including the viewing range of the observation optical systems 2, 7, 8, and 9. Illumination area changing means 16, 17, 18, 19, which can change the illumination area of the illumination light in accordance with the illumination light, and illumination light applied to the first illumination area by the illumination area changing means 16, 17, 18, 19, The focus positions of the observation optical systems 2, 7, 8, and 9 control the second illumination area in the first illumination area. Illumination area limiting means 12 provided at a position on the optical path of the illumination light conjugate with a position at the focal position on the optical path of the illumination light so that the illumination light can be emitted. , 13, 14, and 15 are provided. In the present embodiment, the illumination light is detected without passing through the variable focal length objective optical system. Since irradiation is performed on the surface, the occurrence of flare is prevented as much as possible.
[0029]
As described above, the surgical microscope according to the present embodiment irradiates illumination light onto the operative site P without passing through the variable focal length objective optical system 2, and performs observation by changing the surface to be observed (operative site). The optical member in the illumination optical system moves in conjunction with the movement of the focal position in the optical system. Therefore, the illumination light having the illumination field diameter that matches the observation field diameter is always illuminated on the observation surface, and the illumination field stop is always arranged at a position conjugate with the observation surface. Irrespective of the focal length, the illumination efficiency is always high, and the best illumination state that does not adversely affect the observation optical system, such as flare, can be obtained.
[0030]
In addition, the surgical microscope of the present embodiment guides illumination light to the operative site by the illumination prism 20 disposed at a position other than the observation light beam. All the reflected light at P, that is, the observation light, can be taken into the observation visual field. Therefore, an extremely bright observation image is obtained.
[0031]
3 and 4 show a second embodiment of the present invention. The same components as those in the first embodiment are denoted by the same reference numerals, and description thereof will be omitted.
FIG. 3 shows a configuration of the mirror unit 30 in the present embodiment. In the drawing, reference numeral 31 denotes a gear arranged so as to mesh with the gear 4 described above, and reference numeral 32 denotes a motor with an encoder having a gear 31 attached to a rotating shaft thereof. The motor with encoder 32 is fixed inside the mirror unit 30. Reference numeral 33 denotes an illumination optical axis O₂  An illumination field stop frame 34 which is arranged and fixed on the upper side and holds the illumination field aperture 12 therein, is provided inside the illumination field aperture frame 33, especially its illumination optical axis O.₂  It is a pupil filter that is detachably disposed at the center position of the illumination field stop 12 above.
[0032]
Reference numeral 35 denotes a first illumination optical system that changes the focal length by changing the relative position of the constituent lens groups, and reference numeral 36 denotes a lens that configures the first illumination optical system 35 in accordance with its rotation operation. The lens frame (not shown) holding the group is₂  A lens group moving member which moves in the direction and changes the relative position of the lens group, reference numeral 37 denotes a gear integrally attached to the lens group moving member 36, and reference numeral 38 denotes a gear arranged so as to mesh with the gear 18. The output shaft of a motor 39 with an encoder is attached to the center of rotation, and the motor 39 with an encoder is fixed inside the mirror unit 30.
[0033]
Reference numeral 40 denotes a second illumination optical system that changes the illumination magnification by changing the distance between the constituent lens groups, and reference numeral 41 denotes a lens that configures the second illumination optical system 40 according to its rotation operation. The lens frame (not shown) holding the group is₂  A lens group moving member that moves in the direction and changes the relative position of the lens group, reference numeral 42 denotes a gear integrally attached to the lens group moving member 41, and reference numeral 43 denotes a gear arranged to mesh with the gear 42. Similarly, the output shaft of the motor with encoder 45 is attached to the center of rotation, and the motor with encoder 45 is also fixed inside the mirror unit 30. Reference numeral 46 denotes the observation optical axis O.₁  And illumination optical axis O₂  Is a half mirror disposed and fixed below the variable focal length objective optical system 2 such that its reflection surface is located on the intersection with the objective lens.
[0034]
Next, the operation of the motors with encoders 32, 39, and 45 will be described with reference to the electric block diagram shown in FIG.
Reference numeral 47 denotes a switch for operating the variable focal length objective optical system 2, reference numeral 48 denotes a switch circuit connected to the switch 47, and reference numeral 49 denotes a drive circuit that outputs a drive signal to the encoder motor 32 based on a signal from the switch circuit 48. is there. Reference numeral 50 denotes a focal length detection circuit connected to the motor 32 with an encoder, 51 denotes an illumination magnification calculation circuit that calculates an illumination magnification based on an output signal of the focal length detection circuit 50, and 52 denotes an output of the illumination magnification calculation circuit 51. This is a drive circuit that outputs a drive signal to the motor with encoder 45 based on the signal. The motor with encoder 45 is electrically connected to the illumination magnification calculation circuit 51. Reference numeral 53 denotes an illumination optical system focal length arithmetic circuit that calculates the focal length of the illumination optical system composed of the first illumination optical system 35 and the second illumination optical system 40, and 54 denotes an output signal of the illumination optical system focal length arithmetic circuit 53. Is a drive circuit that outputs a drive signal to the motor 39 with the encoder based on. The motor with encoder 39 is electrically connected to the illumination optical system focal length calculation circuit 53.
[0035]
Since the present embodiment is configured as described above, during the operation, the operator operates the switch 47 to change the focal length by the variable focal length objective optical system 2 in the same manner as in the first embodiment, so that the focus is changed. When the adjustment is performed, an operation signal is output to the drive circuit 49 by the switch circuit 48, and a drive signal is output from the drive circuit 49 to the encoder-equipped motor 32 according to the operation signal. Thus, the motor with encoder 32 is driven, and the lens group moving member 3 is rotated via the gear 31.
[0036]
With the rotation of the lens group moving member 3, a specific lens group among the lens groups constituting the variable focal length objective optical system 2 is moved along the optical axis O.₁  , The relative position of the lens group changes, the focal length reaches a desired value, and focusing is performed. At this time, the rotation angle of the lens group moving member 3 is output to the focal length detection circuit 50 by the motor 32 with the encoder, so that the focal length detection circuit 50 converts the rotation angle signal of the lens group moving member 3 into a focal length variable objective optical. The focal length of the system 2 is calculated.
[0037]
Based on the focal length information from the focal length detection circuit 50, the illumination magnification calculation circuit 51 determines that the observation field diameter and the illumination field diameter match on the surgical site P, that is, on the focal length of the variable focal length objective optical system 2. The target illumination magnification is calculated, and the calculation result is output to the drive circuit 52. The drive circuit 52 outputs a drive signal to the motor 45 with the encoder according to the output signal from the illumination magnification calculation circuit 51, and the motor 45 with the encoder is driven.
[0038]
Therefore, the lens group moving member 41 is rotated via the gear 43, and the lens group forming the second illumination optical system 40 is moved to the illumination optical axis O.₂  Along, the illumination magnification is changed. At this time, the rotation angle of the lens group moving member 41 is fed back to the illumination magnification calculation circuit 51 by the encoder motor 45, and the illumination magnification is calculated one by one. The drive circuit 52 outputs the illumination magnification until the illumination magnification reaches the target illumination magnification described above. A drive signal is output, and the motor with encoder 45 is driven.
[0039]
The focal length signal of the variable focal length objective optical system 2 is input from the focal length detection circuit 50 to the illumination optical system focal length calculation circuit 53. The illuminating optical system focal length calculation circuit 53, based on the focal length signal, calculates the operative site P and the illuminating optical axis O₂  The target focal length of the illumination optical system including the first illumination optical system 35 and the second illumination optical system 40 is calculated so that the fixed position of the illumination field stop 12 above has an optically conjugate positional relationship. . Based on the calculation result, a drive signal is output from the drive circuit 54 to the motor 39 with the encoder, and the motor 39 with the encoder is driven by the drive signal.
[0040]
Therefore, the lens group moving member 36 is rotated via the gear 38, and the lens group forming the first illumination optical system 35 is moved to the illumination optical axis O.₂  Moving upward, the focal length of the illumination optical system constituted by the first illumination optical system 35 and the second illumination optical system 40 is changed. At this time, the rotation angle of the lens group moving member 36 is fed back to the illumination optical system focal length calculation circuit 53 by the motor 39 with the encoder, and the focal length of the illumination optical system is calculated one by one. , The drive signal is output from the drive circuit 54, and the motor 39 with the encoder is driven. Further, by inserting the pupil filter 34 at the position of the illumination field stop 12 in the illumination field aperture frame 33, the pupil filter 34 is arranged and fixed at a position conjugate with the operative site P.
[0041]
As described above, also in the present embodiment, the illumination light is irradiated onto the surgical site P without passing through the variable focal length objective optical system 2, and the focal point in the observation optical system due to the change in the surface to be observed (operative site). The optical member in the illumination optical system moves in conjunction with the movement of the position. Therefore, the illumination light having the illumination field diameter that matches the observation field diameter is always illuminated on the observation surface, and the illumination field stop is always arranged at a position conjugate with the observation surface. Irrespective of the focal length, the illumination efficiency is always high, and the best illumination state that does not adversely affect the observation optical system, such as flare, can be obtained.
[0042]
Further, in this embodiment, the illumination optical axis O in the mirror body 30 is set.₂  Since the conjugate position with the operation part P does not change, the illumination field stop frame 33 can be fixed in the mirror body part 30. Therefore, with a simple configuration, the pupil filter 34 can be inserted and removed at a position conjugate with the operative site P as needed, which helps protect the retina of the patient.
[0043]
FIGS. 5 to 7 show the configuration of a surgical microscope that irradiates irradiation light to an operation site via an objective optical system. The same components as those in the first and second embodiments are denoted by the same reference numerals, and description thereof will be omitted.
[0044]
FIG. 5 is a configuration diagram of the mirror unit and the illumination unit of the surgical microscope, and FIG. 6 is a configuration diagram of the aperture stop unit in FIG. 5 and is a view of the mirror unit from the operation unit P side in FIG. FIG. 7 is a diagram developed in the direction of the operative site P in FIG. 5 in order to clarify the configuration. FIG. 7 is a configuration diagram of a driving unit of the lighting unit in FIG.
[0045]
Next, the configurations of the mirror unit and the illumination unit will be described with reference to FIG. Reference numeral 60 denotes a mirror unit, 61 denotes an illumination unit, and a pair of lamps 10, a condenser lens 11, and an illumination field stop disposed inside the illumination unit, symmetrically with respect to the center of both left and right observation optical axes. 12, an illumination optical system 16, an aperture stop unit 62 and an objective lens 63, which will be described later.
[0046]
Next, the configuration of the aperture stop unit 62 will be described with reference to FIG. Reference numeral 64 denotes an aperture stop that includes stop members 65 and 66 whose reflection surfaces are formed by mirrors. One end of each of the aperture members 65 and 66 is held by a guide rod 67.
[0047]
Reference numeral 68 denotes a right screw lead provided at the other end of the aperture member 66, and reference numeral 69 denotes a left screw lead similarly provided at the other end of the aperture member 66. Reference numeral 70 denotes a shaft having a right-handed lead screw 71 that meshes with the lead screw 68 and a left-handed lead screw 72 that meshes with the lead screw 69. Both ends of the shaft 70 are rotatably held in the housing of the aperture stop unit 62 by bearings 73 and 74.
[0048]
Reference numeral 75 denotes a gear fixed to one end of the shaft 70. Reference numeral 76 denotes a gear arranged so as to mesh with the gear 75, and an aperture stop adjusting knob 77 is attached to the central axis of the gear. Reference numeral 78 denotes a gear whose central axis is attached to the brightness adjustment knob 77, 79 denotes a gear arranged to mesh with the gear 78, and 80 denotes a gear arranged to mesh with the gear 79. The aperture stop unit 62 has the same configuration (same configuration as in the first and second embodiments) symmetrically with respect to the center of the left and right observation optical axes via gears 78, 79, and 80. are doing. The operation direction of the aperture stop adjustment knob 77 is indicated by an arrow in the figure. The moving directions of the stop members 65 and 66 that are moved by operating the aperture stop adjustment knob 77 are indicated by arrows in the figure.
[0049]
Next, the configuration of the driving unit of the lighting unit 61 will be described with reference to FIG. Reference numeral 84 denotes a motor operated by input means (for example, a foot switch) (not shown), which is fixed inside the mirror unit 60. Reference numeral 85 denotes a gear attached to the rotating shaft of the motor 84, and reference numeral 86 denotes a gear arranged to mesh with the gear 85 and to mesh with a rack 87 attached to the housing of the lighting unit 61. Reference numeral 88 denotes a guide rod that holds the illumination unit 61, and both ends of the guide rod are fixed to the housing of the mirror unit 60. The moving direction of the lighting unit 61 is indicated by an arrow in the figure.
[0050]
In the surgical microscope configured as described above, when the operator operates input means (not shown) to perform focusing during the operation, the motor 84 rotates, and the gears 85 and 86 and the rack 87 are moved. Through this, the illumination unit 61 moves in the direction of the arrow in the drawing, that is, in the observation optical axis direction with respect to the mirror unit 60, and focus is performed. At this time, with the movement of the objective lens 63 included in the illumination unit 61, the aperture stop unit 62, the illumination field stop 12, the illumination optical system 16, the condenser lens 11, and the lamp 10 also move in the observation optical axis direction at the same time. Therefore, the relative positional relationship between the optical members in the illumination unit 61 does not change. In addition, since the focal length of the objective lens itself does not change, the image of the illumination field stop 12 is projected onto the operation portion P, which is a conjugate position on the observation optical axis, that is, the focal position without changing the illumination field diameter. You. Therefore, the observation visual field diameter and the illumination field diameter are always kept in agreement.
[0051]
When the operator turns the aperture stop adjustment knob 77 in the lower arrow direction in the drawing, that is, clockwise to adjust the depth of focus, the shaft 70 rotates via the gears 76 and 75. At this time, since the lead screw portions 68 and 71 are configured with right-hand threads and the lead screw portions 69 and 72 are configured with left-hand threads, the diaphragm member 65 moves rightward in the drawing and the diaphragm member 66 moves leftward in the drawing. Therefore, the aperture stop 64 is stopped down, and the depth of focus is increased. At this time, since the reflecting surfaces of the diaphragm members 65 and 66 inserted on the illumination light flux are constituted by mirrors as described above, the illumination light increases more as the area of the reflecting surface increases. Irradiated on top. Conversely, when the aperture stop 67 is turned in the direction of the upper arrow in the drawing, that is, counterclockwise, the stop member 65 moves leftward in the drawing and the stop member 66 moves rightward in the drawing. The aperture 64 is opened. Therefore, although the depth of focus becomes shallow, at this time, the illumination light illuminated on the operative site P decreases as the area of the reflection surfaces of the diaphragm members 65 and 66 inserted on the illumination light flux decreases. In addition, the same operation as described above can be naturally performed for the aperture stop disposed on the other optical path via the gears 78, 79, and 80.
[0052]
As described above, in the surgical microscope of this configuration, the illumination field stop 12 and the operative site P are always maintained in a conjugate positional relationship with a simple configuration in which the entire illumination unit is moved in the observation optical axis direction. . Further, even if the surgeon adjusts the brightness stop 64 so as to change the depth of focus in accordance with the operation method or the surgical site, the size of the aperture of the aperture stop 64 automatically causes the illumination light to be automatically displayed on the object plane. Since the amount of irradiation of the light is adjusted, the brightness in the observation visual field is always kept constant, and the illumination efficiency is further improved.
[0053]
【The invention's effect】
As explained above,According to the surgical microscope of the present invention,Illumination light with an illumination field diameter that matches the observation field diameter is always illuminated on the surface to be inspected, and a projection optical member such as an illumination field stop or a pupil filter is always arranged at a position conjugate with the surface to be inspected. Therefore, the illumination efficiency is always high regardless of the focal length of the surface to be inspected, and the best illumination state that does not adversely affect the observation optical system such as flare can be obtained.
[Brief description of the drawings]
FIG. 1 is a configuration diagram of a mirror section of a surgical microscope according to a first embodiment of the present invention.
FIG. 2 is a diagram showing a positional relationship between an illumination field stop and an operation part P in the surgical microscope of FIG. 1;
FIG. 3 is a configuration diagram of a mirror section of a surgical microscope according to a second embodiment of the present invention.
FIG. 4 is a block diagram of a drive circuit that drives the optical system of FIG.
FIG. 5 is a configuration diagram of a mirror unit and a lighting unit of the surgical microscope.
6 is a structural view of the aperture stop unit in the illumination unit of FIG.
7 is a configuration diagram of a driving unit of the lighting unit in FIG.
FIG. 8 is an overall configuration diagram of a conventional surgical microscope.
FIG. 9 is a configuration diagram of a mirror unit having a variable focal length objective optical system.
FIG. 10 is a configuration diagram of a mirror unit in which a variable focal length objective optical system is applied to complete coaxial illumination.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Mirror part, 2 ... Variable focal length objective optical system, 5, 15, 19, 31, 43, 38 ... Gear, 6, 32, 39, 45 ... Motor, 12 ... Illumination stop (optical member), 13 ... Illumination aperture frame, 14 rack, 16, 35, 40 illumination optical system (optical member), 17 lens group moving member, 21 gear box, 46 half mirror.

Claims (2)

An observation optical system for the operator to observe the subject,
Focus position changing means capable of changing the focus position of the observation optical system,
A light source capable of emitting illumination light for illuminating an observation position of the subject observed by the observation optical system,
An illumination magnification changing unit disposed on an optical path of the illumination light from the light source to the observation position, and changing an illumination magnification of illumination light applied to the observation position in accordance with a change of a focal position by the focal position changing unit; When,
Illumination area changing means for limiting the luminous flux of the illumination light and changing the illumination area of the illumination light illuminated at the observation position,
The illumination magnification changing means and the illumination area change according to a change in the illumination magnification of the illumination magnification changing means so that the illumination area changing means is arranged at a position conjugate to the observation position on the optical path of the illumination light. Means for changing the relative positional relationship with the means,
An operating microscope comprising: An observation optical system for the operator to observe the subject,
Focus position changing means capable of changing the focus position of the observation optical system,
A light source capable of emitting illumination light for illuminating an observation position of the subject observed by the observation optical system,
An illumination magnification changing unit disposed on an optical path of the illumination light from the light source to the observation position, and changing an illumination magnification of illumination light applied to the observation position in accordance with a change of a focal position by the focal position changing unit; When,
Is arranged at a predetermined position on the optical path of the illumination light, an illumination area changing unit for changing an illumination region of the illumination light morphism irradiation to the observation position to limit the light flux of the illumination light,
A conjugate position changing unit disposed on an optical path of the illumination light, and changing a position conjugate with the observation position on the optical path of the illumination light to the predetermined position according to a change in illumination magnification of the illumination magnification changing unit; ,
An operating microscope comprising:

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